Increased Belowground Carbon Allocation Reduces Soil Carbon Losses Under Long-Term Warming

Schindlbacher, Andreas; Kwatcho Kengdo, Steve; Heinzle, Jakob; Tian, Ye; Mayer, Mathias; Gadermaier, Josef; Shi, Chupei; Malo, Caro Urbina; Liu, Xiaofei; Inselsbacher, Erich; Jandl, Robert; Sierra, Carlos A.; Wanek, Wolfgang; Borken, Werner

doi:10.1111/gcb.70561

Forskningsartikel2025Vetenskapligt granskadÖppen tillgång

Increased Belowground Carbon Allocation Reduces Soil Carbon Losses Under Long-Term Warming

Schindlbacher, Andreas; Kwatcho Kengdo, Steve; Heinzle, Jakob; Tian, Ye; Mayer, Mathias; Gadermaier, Josef; Shi, Chupei; Malo, Caro Urbina; Liu, Xiaofei; Inselsbacher, Erich; Jandl, Robert; Sierra, Carlos A.; Wanek, Wolfgang; Borken, Werner

Sammanfattning

The response of the carbon cycle in forests to global warming could lead to a positive climate feedback if warming accelerates the mineralization of soil organic carbon (SOC), thereby causing net emissions of CO2 into the atmosphere. In Europe, carbon-rich alpine forest soils could be particularly affected by global warming, as a greater rise in temperature is expected in this region than the global average. Here we show that nearly two decades of experimental soil warming (+4 degrees C during the snow-free seasons) in a mountain forest in the Northern Limestone Alps significantly (similar to 13% per 1 degrees C warming) and persistently (no change in response over 18 years) increased soil CO2 effluxes. The SOC stocks in the warmed plots decreased compared to controls, yet non-significantly, and quantitatively much less than the surplus carbon outflux from warmed soil suggests. We attribute the increase in soil CO2 efflux primarily to stimulation of root respiration, which was most sensitive to long-term warming. Furthermore, increased root production, faster fine root turnover, and increased root exudation likely not only facilitated autotrophic respiration but also replenished the SOC pool. The radiocarbon age of SOC indicates a rejuvenation of SOC likely by increased input of root carbon into the lower topsoil. Overall, our findings suggest that increased C allocation into the rhizosphere can at least partially compensate for the C loss through increased SOC mineralization with rising temperatures over many years.

Nyckelord

radiocarbon; root respiration; roots; soil CO2 efflux; soil organic carbon; warming

Publicerad i

Global Change Biology
2025, volym: 31, nummer: 10, artikelnummer: e70561
Utgivare: WILEY

SLU författare

Tian, Ye
- Institutionen för mark och miljö, Sveriges lantbruksuniversitet
- Universität Wien

UKÄ forskningsämne

Miljövetenskap
Markvetenskap

Publikationens identifierare

DOI: https://doi.org/10.1111/gcb.70561

Permanent länk till denna sida (URI)

https://res.slu.se/id/publ/144475